Physics-Informed Neural Network Method for Parabolic Differential
Equations with Sharply Perturbed Initial Conditions
- URL: http://arxiv.org/abs/2208.08635v1
- Date: Thu, 18 Aug 2022 05:00:24 GMT
- Title: Physics-Informed Neural Network Method for Parabolic Differential
Equations with Sharply Perturbed Initial Conditions
- Authors: Yifei Zong and QiZhi He and Alexandre M. Tartakovsky
- Abstract summary: We develop a physics-informed neural network (PINN) model for parabolic problems with a sharply perturbed initial condition.
Localized large gradients in the ADE solution make the (common in PINN) Latin hypercube sampling of the equation's residual highly inefficient.
We propose criteria for weights in the loss function that produce a more accurate PINN solution than those obtained with the weights selected via other methods.
- Score: 68.8204255655161
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: In this paper, we develop a physics-informed neural network (PINN) model for
parabolic problems with a sharply perturbed initial condition. As an example of
a parabolic problem, we consider the advection-dispersion equation (ADE) with a
point (Gaussian) source initial condition. In the $d$-dimensional ADE,
perturbations in the initial condition decay with time $t$ as $t^{-d/2}$, which
can cause a large approximation error in the PINN solution. Localized large
gradients in the ADE solution make the (common in PINN) Latin hypercube
sampling of the equation's residual highly inefficient. Finally, the PINN
solution of parabolic equations is sensitive to the choice of weights in the
loss function. We propose a normalized form of ADE where the initial
perturbation of the solution does not decrease in amplitude and demonstrate
that this normalization significantly reduces the PINN approximation error. We
propose criteria for weights in the loss function that produce a more accurate
PINN solution than those obtained with the weights selected via other methods.
Finally, we proposed an adaptive sampling scheme that significantly reduces the
PINN solution error for the same number of the sampling (residual) points. We
demonstrate the accuracy of the proposed PINN model for forward, inverse, and
backward ADEs.
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